Abstract
Here in this research, room temperature ethanol and humidity sensors were prepared based on two dimensional (2D) hybrid nanostructures of tungsten di-sulfide (WS2) nanosheets and graphene oxide nanoribbons (GONRs) as GOWS. The characterization results based on scanning electron microscopy (SEM), energy dispersive X-ray spectroscopy (ESD), Raman spectroscopy and X-ray diffraction (XRD) analysis confirmed the hybrid formations. Ethanol sensing of drop-casted GOWS films on SiO2 substrate indicated increasing in gas response up to 5 and 55 times higher compared to pristine GONRs and WS2 films respectively. The sensing performance of GOWS hybrid nanostructures was investigated in different concentrations of WS2, and the highest response was about 126.5 at 1 ppm of ethanol in 40% relative humidity (R.H.) for WS2/GONRs molar ratio of 10. Flexibility of GOWS was studied on Kapton substrate with bending radius of 1 cm, and the gas response decreased less than 10% after 30th bending cycles. The high response and flexibility of the sensors inspired that GOWS are promising materials for fabrication of wearable gas sensing devices.
Highlights
Room temperature and high response ethanol and humidity sensors were prepared based on 2D hybrid nanostructures of W S2/GONRs by a simple drop-casting method
Morphological and structural analysis of the asprepared samples verified the formation of heterojunction structures between WS2 and GONRs
The sensing performance of GOWS was investigated with different molar ratio of WS2 to GONRs and GOWS10 exhibited the highest response
Summary
Room temperature and high response ethanol and humidity sensors were prepared based on 2D hybrid nanostructures of W S2/GONRs by a simple drop-casting method.
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